Most massively multiplayer online games take place in epic fantasy worlds or the distant future, but one of the latest sensations takes place on a much, much smaller scale. Agar.io pits thousands of players against each other in a web-based petri dish, where each gamer represents a cell. Your only real goal is to grow larger than everyone else by swallowing other cells and dodging your bigger rivals. It sounds simple, but it can get very hectic -- and it's a good abstraction of the fierce survival-of-the-fittest competition that you sometimes see on the microscopic level.

Researchers have had success growing organs in controlled lab environments, but repeating that feat inside a complex, messy animal body? That's more than a little tricky. However, researchers at the University of Edinburgh have managed that daunting feat for the first time. They've grown thymus glands inside lab mice by "reprogramming" the genes in tissue-regenerating cells and partnering those with support cells. The team didn't have to use scaffolds or other "cheats" to trigger the growth; it just injected the cells and waited. There weren't even any obvious limitations. The organs were full size (unlike the baby-like results from some experiments), and they were just as efficient at producing virus-fighting T-cells as the real deal.

Scientists at the Cockrell School of Engineering in Texas have created a nanomotor less than one micrometer in diameter, smaller even than a cell. Powered by electric fields, it consists of a nanowire, magnet and electrode and can spin at a terrifying-sounding 18,000 RPM for over 15 hours (see video below). That's as fast as a jet engine, but don't worry (much). During testing, it showed the ability to pump fluids at hyper-fast speeds and to move around freely in other liquids. That opens up beneficial applications like highly controlled insulin delivery, or devices that could specifically target malignant cells. Of course, that would mean you'd have to let intelligent nano-devices with mini-saws roam about your body -- I guess you're allowed to be a bit terrified.

It's a brand new day for Cricket, AT&T's budget wireless arm. Last year, the mobile giant announced plans to acquire Leap Wireless, Cricket's parent company, and has since launched a major refresh, formally introducing the new service today. After purchasing new devices, Cricket customers will be able to access AT&T's nationwide 4G network, including LTE. All plans include unlimited domestic calling, messaging and international texting to 35 countries, and come in at $35, $45 and $55 monthly (after a $5 auto pay credit), with 500MB, 2.5GB and 5GB of data, respectively. You won't be charged for data overages -- instead, Cricket will cap your speed at 128 Kbps for the rest of the billing period.

It turns out that your biology teacher (and a certain 1997 sci-fi flick) got something wrong -- DNA isn't necessarily limited to four letters. Scripps Research Institute scientists tell Wired that they've created living cells which include two artificial letters (that is, nucleotides) in their genetic code in addition to the naturally occurring A, C, G and T. The researchers' primary obstacle was making sure these nucleotides cooperated with the enzymes that copy and transcribe DNA; after that, it was just a matter of getting some E. coli bacteria to accept and propagate the newly augmented sequences.

It's relatively easy to clone embryos from the adult stem cells of simpler animals like sheep, but humans have proved challenging. Even an attempt last year only used baby cells. The process just took a gigantic step forward, though, as scientists have finally used an adult human's stem cells to clone a pre-embryonic blastocyst. The process was mostly similar to that for other species: researchers removed the DNA from the nucleus of an unfertilized egg and inserted a skin cell into that egg. From there, the team only needed growth chemicals to develop the stem cells into specific cell types, such as heart tissue.

Whether you asked for a curved phone or not, they're already a convex reality. One that introduces a few manufacturing twists. A curved screen is one thing, but what about other large components like the battery? Samsung sidestepped this issue in the Round by making it narrow and tall, but there's still a limit to the amount of curve available. A new flexible battery developed at the New Jersey Institute of Technology could solve that. The cell uses carbon nanotubes, and is not only flexible (like otherexamples we've seen), but entirely scalable -- suitable for tiny or large electronics alike. Not only would this mean roll-up batteries, the researchers claim it could easily be made at home with the right "paste" and a laminating machine.

Previous work on using organisms as circuitry has usually involved shoehorning parts of the digital world into a very analog environment. MIT has just found an approach that uses the subtlety of the natural world to its advantage: the circuits themselves are analog. By combining genes that produce similar molecules in response to different inputs, the school's scientists have created bacterial cells that perform basic math -- the exact quantity or ratio of a given molecule is the answer. The approach offers a much wider range of results than a binary circuit (10,000 versus 2), and it exploits the cell enzymes' inherent ratio awareness to do some of the hard work. MIT wants more variety in genetic ingredients before it can produce a truly universal system, but its work could lead to organic sensors that are much simpler and more precise than their digital peers.

For all the money and effort poured into supercomputers, their lifespans can be brutally short. See IBM's Roadrunner as a textbook example: the 116,640-core cluster was smashing records just five years ago, and yet it's already considered so behind the times that Los Alamos National Laboratory is taking it out of action today. Don't mourn too much for the one-time legend, however. The blend of Opteron and Cell processors proved instrumental to understanding energy flow in weapons while also advancing the studies of HIV, nanowires and the known universe. Roadrunner should even be useful in its last gasps, as researchers will have a month to experiment with the system's data routing and OS memory compression before it's dismantled in earnest. It's true that the supercomputer has been eclipsed by cheaper, faster or greener competitors, including its reborn Cray arch-nemesis -- but there's no question that we'll have learned from Roadrunner's brief moment in the spotlight.

It's easy to find work on gene-based storage; finding genes that will do any of the heavy lifting is another matter. MIT believes it has a genetic circuit that will finally get to work, and then some. In using recombinase enzymes to alter DNA sequences serving as logic gates, researchers have developed a cellular circuit that not only mimics its silicon cousins, but has its own built-in memory. As the gate activation makes permanent changes to a given DNA sequence, any gate actions stay in memory for up to 90 generations -- and will hang around even if the cell's life is cut short. MIT sees its technique as having ultimate uses for areas where longer-term memory is important, such as environmental sensors, but could also see varying output values helping with digital-to-analog converters and other devices where there's a need for more precision. While there's no word on imminent plans for real-world use, the development raises the possibility of processors that could skip the traditional memory cache as they pass info down the family tree.

We've looked intensely at the outside of the redesigned PlayStation 3 ever since it was unveiled in Tokyo last month. Getting a look inside has proven unusually tougher, but French YouTube member K0st3yr has volunteered to do what few gamers dare and tear down Sony's updated console. As we've quickly learned, Sony hasn't chosen to radically rework the insides like Microsoft did with the slim Xbox 360. The Cell processor and its RSX graphics companion are still separate parts, and a similar power supply capacity suggests that neither of the main chips has been built on a more efficient manufacturing process. Instead, it's everything else that has been given the shuffle: a smaller Blu-ray drive and more clever overall construction appear to be the tickets to the 20 percent volume reduction compared to the last model. While the revealed internals might be disappointments to those who were hoping the PS3's possible sendoff would involve more of a bang than a whimper, they do hint that Sony might have breathing room if it wants to advance the design any further. Just have some popcorn and a grasp of French on hand if you'd like to have a peek at the three-part video dissection found after the break.

Update: Not to be outdone, iFixit has conducted its own teardown. There aren't any shockers in the mix beyond improved repairability, but you'll find many of the components given their exact names as well as more explanations of what's been changed to shrink the PS3 a second time.

Electron microscopes can produce incredibly detailed and even 3D views of sub-cellular structures, but often at the cost of losing the bigger picture. Researchers at Leiden University in the Netherlands, however, have leveraged a technique called virtual nanoscopy that enables researchers to observe the whole of a cell and its intricate details in a single image. With the method, the team stitches together nanometer resolution photographs of what's gone under the scope to create a map with adjustable zoom a la Google Maps. Their study created a 281-gigapixel image (packed with 16 million pixels per inch) of a 1.5-millimeter-long zebrafish embryo. If you'd like to take a gander at the ultra-high resolution fish or read up on the group's findings for yourself, check out the source links below.

Believe it or not, EV battery life is still something of a Pandora's Box, even for automakers: they can tell you the battery pack's current and voltage, but not how it's really performing under pressure. Ford, GE and the University of Michigan are uniting to unlock that mystery through a new ARPA-E project. In its role, GE is developing a minuscule sensor array that will track the nuances of battery cells that existing technology misses; it will promptly hand the baton to researchers at the University of Michigan, who plan to both prove that GE's data is on the mark as well as develop tricks for predicting behavior. Ford handles the last mile, almost literally: it's planning to fit the GE sensor technology to one of its cars and test in a more realistic environment. Before you fantasize about knowing the lifespan of your Focus Electric's battery down to the minute, however, the new alliance is stressing that it's only just getting started -- there's another three years and $3.1 million to go before the project wraps up. If all goes according to plan, though, we'll have electric cars and plug-in hybrids that can not only tell when they've seen better days but can eke out extra miles through smarter battery designs.

We've seen fuel cells used in a variety of gadgets -- from cars to portable chargers -- and while medical devices aren't exactly at the top of the list, they're yet another application for these mini power sources. MIT engineers are turning to sugar to make fuel cells for powering brain implants. The scientists developed cells that use platinum to strip electrons from glucose molecules found in a patient's cerebrospinal fluid to create a small electric current. The fuel cells are fabricated on a silicon chip so they can interface with other circuits in a brain implant. The prototype can generate up to hundreds of micro watts, which is enough to power neural implants used to help paralyzed patients move their limbs. Mind you, this technology is years away from making it to market. The next step will be proving that the devices work in animals, which reminds us of one Ricky the rat, who survived a biofuel cell implant back in 2010.

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Wed, 13 Jun 2012 20:53:00 -040021|20257954http://www.engadget.com/2012/04/04/thin-flexible-solar-cells/%3Futm_medium%3Dfeed%26utm_source%3DFeed_Classic%26utm_campaign%3DEngadget%26ncid%3Drss_semi
http://www.engadget.com/2012/04/04/thin-flexible-solar-cells/http://www.engadget.com/2012/04/04/thin-flexible-solar-cells/%3Futm_source%3DFeed_Classic%26utm_medium%3Dfeed%26utm_campaign%3DEngadget%23commentsYou've probably heard that the sun is strong enough to power our planet many times over, but without a practical method of harnessing that energy, there's no way to take full advantage. An incredibly thin and light solar cell could go a long way to accomplishing that on a smaller scale, however, making the latest device from researchers from the University of Austria and the University of Tokyo a fairly significant discovery. Scientists were able to create an ultra-thin solar cell that measures just 1.9 micrometers thick -- roughly one-tenth the size of the next device. Not only is the sample slim -- composed of electrodes mounted on plastic foil, rather than glass -- it's also incredibly flexible, able to be wrapped around a single strand of human hair (which, believe it or not, is nearly 20 times thicker). The scalable cell could replace batteries in lighting, display and medical applications, and may be ready to be put to use in as few as five years. There's a bounty of physical measurement and efficiency data at the source link below, so grab those reading glasses and click on past the break.

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Wed, 04 Apr 2012 13:50:00 -040021|20208262http://www.engadget.com/2012/03/21/republic-wireless-beta/%3Futm_medium%3Dfeed%26utm_source%3DFeed_Classic%26utm_campaign%3DEngadget%26ncid%3Drss_semi
http://www.engadget.com/2012/03/21/republic-wireless-beta/http://www.engadget.com/2012/03/21/republic-wireless-beta/%3Futm_source%3DFeed_Classic%26utm_medium%3Dfeed%26utm_campaign%3DEngadget%23commentsThe $19 all-you-can-eat smartphone service that seemed great, then not-so-great, then great again is about to re-open public beta testing. We're told that the first phase of the beta is "going very well", to the point where Republic Wireless feels it can "skip the baby steps" and offer its hybrid VOIP/cellular goodies to another batch of experimental folks starting in June. The provider also promises a new handset as early as April, a smoother transition between WiFi and cellular calling (on Sprint's frequencies) in May, and a full-on public launch at some point in the undeclared or undecided future. Not ready to abandon your Big Cell provider just yet? Then Republic Wireless makes one more promise: a way for customers with other carriers to save money on their bills even before they make the leap. Consider us intrigued!

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Wed, 21 Mar 2012 07:59:00 -040021|20197682http://www.engadget.com/2012/02/20/nokia-siemens-hspa-multiflow/%3Futm_medium%3Dfeed%26utm_source%3DFeed_Classic%26utm_campaign%3DEngadget%26ncid%3Drss_semi
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If you've ever used a cell phone while moving, then you've probably experienced the depressed network connectivity that becomes more of an issue as you move further away from any given tower. Some of us are even unfortunate enough to reside or work right at the edge of a cell, forced to live with poor connectivity for much of every day. A new feature called HSPA+ Multiflow may offer some relief, "delivering double the data speed and up to 50 percent faster response compared to existing HSPA+ networks," according to Nokia Siemens, which will be demonstrating the technology at Mobile World Congress later this month. Essentially, Multiflow allows compatible devices on the edge of a cell to connect to two sites simultaneously, letting your device send and receive data between two base stations at once. Multiflow will be available as a software update for Single RAN systems, so it could make its way to a cell site near you just after Nokia Siemens flips the switch during the second half of 2013. Full PR is just past the break.

In the pre-smartphone era, the industry focused on making cell phones smaller. In the 2001 movie Zoolander, the title character played by Ben Stiller uses a humorously diminutive flip phone closer to the size of a Bluetooth headset than the StarTAC it parodies. But if the movie were being made today (IMDB lists a sequel slated for 2014), the fictional male model might hold up an iPad 2 or Toshiba Excite to his head: particularly since 2010, phones have been expanding to accommodate their sprawling displays.

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Sun, 12 Feb 2012 18:00:00 -050021|20167446http://www.engadget.com/2011/12/19/scientists-create-first-solar-cell-with-over-100-percent-quantum/%3Futm_medium%3Dfeed%26utm_source%3DFeed_Classic%26utm_campaign%3DEngadget%26ncid%3Drss_semi
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Researchers over at the National Renewable Energy Lab have reportedly made the first solar cell with an external quantum efficiency over 100 percent. Quantum efficiency relates to the number of electrons-per-second flowing in a solar cell circuit, divided by the number of photons from the energy entering. The NREL team recorded an efficiency topping out at 114 percent, by creating the first working multiple exciton generation (MEG) cell. Using MEG, a single high energy photon can produce more than one electron-hole pair per absorbed photon. The extra efficiency comes from quantum dots 'harvesting' energy that would otherwise be lost as heat. The cell itself uses anti-reflection coating on a transparent conductor, layered with zinc oxide, lead selenide, and gold. NREL scientist Arthur J. Nozik predicted as far back as 2001 that MEG would do the job, but it's taken until now for the concept to leap over from theory. The hope is, of course, that this will lead to more competitively priced solar power, fueling the transport of the future.

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Mon, 19 Dec 2011 06:01:00 -050021|20130527http://www.engadget.com/2011/11/23/researchers-create-spinal-cord-connectors-from-human-stem-cells/%3Futm_medium%3Dfeed%26utm_source%3DFeed_Classic%26utm_campaign%3DEngadget%26ncid%3Drss_semi
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It's taken many years and more than a bit of brainpower, but researchers at the University of Central Florida have finally found a way to create neuromuscular connectors between muscle and spinal cord cells, using only stem cells. Led by bioengineer James Hickman, the team pulled off the feat with help from Brown University Professor Emeritus Herman Vandenburgh, who collected muscle stem cell samples from adult volunteers. After close examination, they then discovered that under the right conditions, these samples could be combined with spinal cord cells to form connectors, or neuromuscular junctions, which the brain uses to control the body's muscles. UCF's engineers say the technique, described in the December issue of the journal Biomaterials, marks a major breakthrough for the development of "human-on-a-chip" models -- systems that simulate organ functions and have the potential to drastically accelerate medical research and drug development. These junctions could also pay dividends for research on Lou Gehrig's disease or spinal cord injuries, though it remains unclear whether we can expect to see these benefits anytime soon.

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Wed, 23 Nov 2011 10:03:00 -050021|20112955http://www.engadget.com/2011/10/31/invisible-glass-could-reduce-display-glare-fails-as-food-in-t/%3Futm_medium%3Dfeed%26utm_source%3DFeed_Classic%26utm_campaign%3DEngadget%26ncid%3Drss_semi
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There's nothing worse (seriously, it's scientifically proven) than catching some serious glare on your smartphone, unless you're checking for spinach in your teeth -- but thanks to Nippon Electric Glass' new "invisible glass," an overly reflective surface may be a problem of the past. According to our friends at Tech-On, the company has developed a new type of vitrine that reduces glare by using a special film on each side of the substrate, which allows more light to pass through the layers rather than bounce off the surface. Normal glass reflects around eight percent of light, while the new variety only rebounds 0.5 percent, dramatically reducing the luminous reflectance to around 0.1 percent or lower. Looks like your yearning to purchase this thing is finally justified.

Panasonic and Tesla renewed their corporate weddingvows yesterday, with a new supply agreement on lithium-ion batteries. Under the accord, Panasonic will provide Tesla with cells for some 80,000 cars over the next four years, effectively ensuring that the manufacturer will meet its ramped-up production targets for 2012 -- including more than 6,000 orders for its Model S EV. As for the batteries themselves, they'll be made using Panasonic's nickel-type cathode technology, which, according to the company, will offer the highest energy density known. Of course, we're still awaiting for the Model S to actually enter full production, but you can whet your electric appetite with Panasonic's full press release, available after the break.

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Thu, 13 Oct 2011 07:02:00 -040021|20080518http://www.engadget.com/2011/08/23/east-coast-earthquake-brings-down-cell-phone-landline-service/%3Futm_medium%3Dfeed%26utm_source%3DFeed_Classic%26utm_campaign%3DEngadget%26ncid%3Drss_semi
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You've probably already read about the 5.9 magnitude earthquake that affected the Eastern Seaboard of the United States, and now we're hearing reports that the quake brought down some landline and cell phone service in New York, along with other cities on the East Coast. We've been unable to place calls in New York City using AT&T and Sprint smartphones, as well as office landlines. Are you experiencing issues as well? Let us know in the comments.

Update: Service seems to have been restored in New York City.

Update 2: Verizon Wireless has released the following statement on Twitter: "Seeing no reports of damage to our wireless network. There was some network congestion in the East after tremors. Continuing to monitor."

Update 3: T-Mobile was feeling left out and sent us an email: "T-Mobile's network is experiencing higher call volumes in all areas and counties affected by the earthquake. If customers are experiencing temporary difficultly placing calls due to network congestion, we advise them to use SMS or E-Mail until call volumes return to normal."

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Tue, 23 Aug 2011 14:15:00 -040021|20024893http://www.engadget.com/2011/08/11/photovoltaic-polarizers-could-make-self-charging-smartphone-drea/%3Futm_medium%3Dfeed%26utm_source%3DFeed_Classic%26utm_campaign%3DEngadget%26ncid%3Drss_semi
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There's nothing worse than losing the charge on your iPhone at the company picnic. But fear not, you won't be stranded Twitter-less next to the potato salad if UCLA's new energy recycling LCD technology ever makes it to market. According to its inventors, the traditional LCD polarization process loses as much as 75 percent of light energy -- something that eats around 80 to 90 percent of the device's power. By using polarizing organic photovoltaic cells, however, the LCD-packing gizmo can recycle its own lost backlight energy, keeping itself charged for longer. What's really cool is these cells can recycle indoor or outdoor light as well, so you will essentially never lose a charge -- or have to speak to another human IRL again. Full PR after the break.

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Thu, 11 Aug 2011 01:03:00 -040021|20014491http://www.engadget.com/2011/06/30/embargo-ibm-develops-instantaneous-memory-100x-faster-than-fl/%3Futm_medium%3Dfeed%26utm_source%3DFeed_Classic%26utm_campaign%3DEngadget%26ncid%3Drss_semi
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You've got to hand it to IBM's engineers. They drag themselves into work after their company's 100th birthday party, pop a few Alka-Seltzers and then promptly announce yet another seismic invention. This time it's a new kind of phase change memory (PCM) that reads and writes 100 times faster than flash, stays reliable for millions of write-cycles (as opposed to just thousands with flash), and is cheap enough to be used in anything from enterprise-level servers all the way down to mobile phones. PCM is based on a special alloy that can be nudged into different physical states, or phases, by controlled bursts of electricity. In the past, the technology suffered from the tendency of one of the states to relax and increase its electrical resistance over time, leading to read errors. Another limitation was that each alloy cell could only store a single bit of data. But IBM employees burn through problems like these on their cigarette breaks: not only is their latest variant more reliable, it can also store four data bits per cell, which means we can expect a data storage "paradigm shift" within the next five years. Combine this with Intel's promised 50Gbps interconnect, which has a similar ETA, and data will start flowing faster than booze from an open bar on the boss's tab. There's more detailed science in the PR after the break, if you have a clear head.